Non-Invasive Photoacoustic Imaging of Cerebral Oxygenation and Hemoglobin Content in Awake Mice
Abstract
Introduction
Investigating cerebral oxygen saturation dynamics in awake animal models remains technically challenging due to motion artifacts and anesthesia-related biases. Here, we introduce a novel high-resolution ultrasound-photoacoustic (PA) imaging approach enabling real-time, non-invasive monitoring of deep cerebrovascular oxygenation dynamics in awake mice with intact skulls.
Materials and Methods
Swiss male and female mice (n = 5–6) were head-fixed using a customized holder adapted to the Neurotar Mobile HomeCage floating platform. High-resolution ultrasound combined with PA imaging (VevoLAZR-X, VisualSonics) was used to discriminate oxyhemoglobin, deoxyhemoglobin, and total hemoglobin in multiple brain regions. Cerebrovascular responses were assessed under three paradigms: (i) baseline awake state vs. 2% isoflurane anesthesia, and (ii) right whisker stimulation to probe sensory-driven hemodynamics.
Results
PA imaging successfully resolved deep-brain oxygenation in awake, intact-skull mice. Under isoflurane anesthesia, we observed a rapid and transient increase in cerebrovascular sO□ (p < 0.01). During whisker stimulation, we detected robust, region-specific increases in total hemoglobin, reflecting localized neurovascular coupling in awake mice.
Conclusions
This study establishes high-resolution PA imaging as a powerful, non-invasive tool to monitor cerebrovascular oxygenation dynamics in awake mice. By integrating baseline, anesthetic, and sensory paradigms, we demonstrate its potential to dissect neurovascular physiology without the confounding effects of anesthesia. These findings provide new opportunities for preclinical neuroscience research and translational applications investigating cerebral oxygen metabolism.
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